Cells that feed on human blood might one day power pacemakers

London, April 2 (ANI): Scientists have created tiny microbial fuel cells by encapsulating yeast cells in a flexible capsule, which can generate power from a drop of human blood plasma, and might one day energize implants such as pacemakers.

According to a report in New Scientist, the cells, developed by a team at the University of British Columbia (UBC) in Vancouver, Canada, can feed on the glucose in human blood.

Such fuel cells would be especially useful for devices, such as intraspinal microelectrodes for treating paralysis, which need to be implanted in places where replacing a battery is tricky, according to Mu Chiao, who co-authored the paper with Chin-Pang-Billy Siu, also at UBC.

Conventional fuel cells rely on high-temperature catalysts such as platinum to strip electrons from fuels and generate a current.

The idea with microbial fuel cells, which are being investigated as large-scale power sources is to exploit the wide range of low-temperature catalysts - enzymes - found in living cells.

The easiest way to do this is to simply steal the electrons produced when cells start to break down food.

This can be done with the help of an “electron mediator” - a chemical small enough to pass into cells, grab some electrons, and diffuse out again.

The new fuel cell consists of a colony of Saccharomyces cerevisiae - the kind of yeast commonly used in brewing and baking - encapsulated in a fuel cell made of a form of silicone called polydimethylsiloxane (PDMS).

The prototype is 15 millimetres square and 1.4 mm thick.

Methyl blue - a chemical often used to stain biological samples - is used as the electron mediator.

This steals some of the electrons produced when the yeast metabolises glucose and delivers them to the anode side of the cell - creating a small current.

On the cathode side, hydrogen ions that diffuse out of the yeast cells combine with oxygen to create water.

To increase the surface area of the electrodes and thus boost the fuel cell’s power output, the team used a silicon etching technique to create “micropillars” roughly 40 micrometers square and 8 micrometers high.